This work is licensed under the Creative Commons Attribution 4.0 International License.
Athanasopoulos G., Pelekis, P. (2000), Ground vibrations from sheetpile driving in urban environment: measurements, analysis and effects on buildings and occupants. 19, 371–387.AthanasopoulosG.PelekisP.200019371387Search in Google Scholar
Brząkała W., Baca M. (2017), The measurement and control of building vibrations in course of sheet pile wall and Franki pile driving, 17th Int. Multidisciplinary Scientific GeoConference, SGEM 2017, 29 June–5 July, Albena, Bulgaria, Vol. 17, Hydrogeology, engineering geology and geotechnics. Iss. 12, Science and technologies in geology, exploration and mining. Sofia: STEF92 Technology, pp. 929–936.BrząkałaW.BacaM.2017The measurement and control of building vibrations in course of sheet pile wall and Franki pile driving17th Int. Multidisciplinary Scientific GeoConference, SGEM2017, 29 June–5 JulyAlbena, Bulgaria17SofiaSTEF92 Technology929936Search in Google Scholar
Oliveira F., Fernandes I. (2017), Influence of geotechnical works on neighboring structures, 17th Int. Multidisciplinary Scientific GeoConference, SGEM 2017, 29 June–5 July, Albena, Bulgaria, Vol. 17, Hydrogeology, engineering geology and geotechnics. Iss. 12, Science and technologies in geology, exploration and mining. Sofia: STEF92 Technology, pp. 993–1001.OliveiraF.FernandesI.2017Influence of geotechnical works on neighboring structures17th Int. Multidisciplinary Scientific GeoConference, SGEM2017, 29 June–5 JulyAlbena, Bulgaria17SofiaSTEF92 Technology9931001Search in Google Scholar
Wojtowicz A., Michałek J., Ubysz A. (2019), Range of dynamic impact of geotechnical works on reinforced concrete structures, E3S Web Conf., vol. 97, 03026.WojtowiczA.MichałekJ.UbyszA.2019Range of dynamic impact of geotechnical works on reinforced concrete structures9703026Search in Google Scholar
Dobrzycki P., Ivannikov A.L., Rybak J., Shkodkina V.O., Tyulyaeva Y. (2019), The impact of Rapid Impulse Compaction (RIC) of large non-cohesive material deposits on the surrounding area. IOP Conf. Ser.: Earth Environ Sci., 2019, 362(1), 012132.DobrzyckiP.IvannikovA.L.RybakJ.ShkodkinaV.O.TyulyaevaY.2019The impact of Rapid Impulse Compaction (RIC) of large non-cohesive material deposits on the surrounding area20193621012132Search in Google Scholar
Golik V.I., Kongar-Syuryun C.B., Michałek A., Pires P., Rybak A. (2021), Ground transmitted vibrations in course of innovative vinyl sheet piles driving. Journal of Physics: Conf. Ser., 1921(1), 012083.GolikV.I.Kongar-SyuryunC.B.MichałekA.PiresP.RybakA.2021Ground transmitted vibrations in course of innovative vinyl sheet piles driving19211012083Search in Google Scholar
Herbut A., Khairutdinov M.M., Kongar-Syuryun C., Rybak J. (2019), The surface wave attenuation as the effect of vibratory compaction of building embankments. IOP Conf. Ser.: Earth Environ Sci., 362(1), 012131.HerbutA.KhairutdinovM.M.Kongar-SyuryunC.RybakJ.2019The surface wave attenuation as the effect of vibratory compaction of building embankments3621012131Search in Google Scholar
Jakubczyk-Gałczyńska A., Jankowski R. (2014), Traffic-induced vibrations. The impact on buildings and people. Proceedings of the 9th International Conference “ENVIRONMENTAL ENGINEERING” 22–23 May 2014, Vilnius, Lithuania, VGTU Press Selected Papers, Article number enviro.2014.028Jakubczyk-GałczyńskaA.JankowskiR.2014Proceedings of the 9th International Conference “ENVIRONMENTAL ENGINEERING”22–23 May 2014Vilnius, LithuaniaVGTU Press Selected Papers, Article number enviro.2014.028Search in Google Scholar
Valaskova V., Papan D., Papanova Z. (2018), Traffic seismicity effect on monumental buildings – results of case studies. J. Meas. Eng. 6(4), 210–217ValaskovaV.PapanD.PapanovaZ.2018Traffic seismicity effect on monumental buildings – results of case studies64210217Search in Google Scholar
Papan D., Papanova Z., Krkoskova K (2019), Experimental dynamic analysis of traffic seismicity effect on historical building. E3S Web Conferences 106, 01018.PapanD.PapanovaZ.KrkoskovaK2019Experimental dynamic analysis of traffic seismicity effect on historical building10601018Search in Google Scholar
Wyjadłowski M. (2017), Methodology of dynamic monitoring of structures in the vicinity of hydrotechnical works – selelced case studies, Studia Geotechnica et Mechanica, Vol. 39, No. 4, 121–129.WyjadłowskiM.2017Methodology of dynamic monitoring of structures in the vicinity of hydrotechnical works – selelced case studies394121129Search in Google Scholar
Jakubczyk-Gałczyńska, A., Jankowski, R. (2020). A Proposed Machine Learning Model for Forecasting Impact of Traffic-Induced Vibrations on Buildings. In: Computational Science – ICCS 2020. Lecture Notes in Computer Science, 12139. Springer, Cham. (140)Jakubczyk-GałczyńskaA.JankowskiR.2020In:Computational Science – ICCS 2020Lecture Notes in Computer Science, 12139.Springer, Cham.140Search in Google Scholar
Łupieżowiec M. (2021), Modelowanie zjawiska rozchodzenia się drgań powstałych od impulsów technologicznych w ośrodku gruntowym. Wydawnictwo Politechniki Śląskiej Gliwice 2021.ŁupieżowiecM.2021Wydawnictwo Politechniki Śląskiej Gliwice2021Search in Google Scholar
Łupieżowiec M. (2021), Modeling the Phenomenon of Propagation of Technological Impulses in Subsoil, Int. J. Geomech., 2022, 22(10): 04022175ŁupieżowiecM.2021Modeling the Phenomenon of Propagation of Technological Impulses in Subsoil2022221004022175Search in Google Scholar
Herbut A. (2021), Aktywna ochrona dynamiczna konstrukcji przez redukcję amplitudy fali propagującej w podłożu gruntowym, Oficyna Wydawnicza Politechniki Wrocławskiej, Wrocław 2021.HerbutA.2021Oficyna Wydawnicza Politechniki WrocławskiejWrocław2021Search in Google Scholar
Prawo ochrony środowiska z dnia 27 kwietnia 2001r., Dz. U. z 2021 r. poz. 1973, 2127, 2269, z 2022 r. poz. 1079 (Environmental Protection Law, in Polish).Search in Google Scholar
Ustawa Prawo budowlane z dnia 7 lipca 1994r., Dz. U. z 2021 r. poz. 2351, z 2022 r. poz. 88 (Construction Law, in Polish)Search in Google Scholar
Dyrektywa 2003/35/WE Parlamentu Europejskiego i Rady z 26 maja 2003r. (in Polish).Search in Google Scholar
Dyrektywa 2001/42/WE Parlamentu Europejskiego i Rady z 27 czerwca 2001r. (in Polish).Search in Google Scholar
BS 5228-4:1992. (1992). British standard. Noise control on construction and open sites. Part 4: Code of practice of noise and vibration control applicable to piling operation.BS 5228-4:19921992Search in Google Scholar
BS 7385-2:1993. (1993). Evaluation and measurement for vibration in buildings — Part 2: Guide to damage levels from ground borne vibrationBS 7385-2:19931993Search in Google Scholar
DIN 4150-3:1999. (1999). Structural vibration Part 3: Effects of vibration on structures.DIN 4150-3:19991999Search in Google Scholar
SN 640312:1992 Vibrations - vibration effects in buildings.SN 640312:1992Search in Google Scholar
Circulaire du 23/07/86 relative aux vibrations mécaniques émises dans l’environnement par les installations classées pour la protection de l’environnement (in French).Search in Google Scholar
Eurocode3, E. 1.-5. (1998). Design of steel structures – part 5. Piling.Eurocode3, E. 1.-51998Search in Google Scholar
SN 640312:1992 Vibrations - vibration effects in buildings.SN 640312:1992Search in Google Scholar
FTA standards (2006) Transit, noise and vibration impact assessment.FTA standards2006Search in Google Scholar
American Association of State Highway and Transportation Officials (AASHTO) (1990), Standard recommended practice for evaluation of transportation-related earthborn vibrations, Washington, DC.American Association of State Highway and Transportation Officials (AASHTO)1990Washington, DCSearch in Google Scholar
PN-B-02170:2016-12. Ocena szkodliwości drgań przekazanych przez podłoże na budynki, 2016 (in Polish).PN-B-02170:2016-122016(in Polish)Search in Google Scholar
PN-B-02171:2017-06. Ocena wpływu drgań na ludzi w budynkach, 2017, (in Polish)PN-B-02171:2017-062017(in Polish)Search in Google Scholar
Dulińska J., Kawecki J., Kozioł K., Stypuła K., Tatara T. (2014), Oddziaływania Parasejsmiczne Przekazywane na Obiekty Budowlane. Wydawnictwo Politechniki Krakowskiej, Kraków (in Polish).DulińskaJ.KaweckiJ.KoziołK.StypułaK.TataraT.2014Wydawnictwo Politechniki KrakowskiejKraków(in Polish).Search in Google Scholar
Stypuła K., Kawecki J. (2008), Błędy w prognozowaniu i diagnostyce wpływów dynamicz-nych na budynki. Czasopismo Techniczne, 105(1–M), 127–136 (in Polish).StypułaK.KaweckiJ.2008Błędy w prognozowaniu i diagnostyce wpływów dynamicz-nych na budynki1051–M127136(in Polish).Search in Google Scholar
Gorska K., Brzakała W. (2008), On safety of slurry-wall trenches. Stud. Geotech. Mech., 30, 198–206.GorskaK.BrzakałaW.2008On safety of slurry-wall trenches30198206Search in Google Scholar
Urbański A., Michalski Ł. (2015), Finite element analysis of lateral earth pressure on a lagging in soldier pile walls Technical Transactions. Environment Engineering, Czasopismo Techniczne. Środowisko, Y. 112, Iss. 24, 171–185.UrbańskiA.MichalskiŁ.2015Finite element analysis of lateral earth pressure on a lagging in soldier pile walls Technical Transactions11224171185Search in Google Scholar
Kabała C., Bekier J., Bińczycki T., Bogacz, A., Bojko, O., Cuske, M., Ćwieląg-Piasecka I., Dębicka, M.; Gałka, B.; Gersztyn, L., (2015); et al. Soils of Lower Silesia: Origins, Diversity and Protection; Kabała, C., Ed.; Polish Society of Soil Science, Wrocław Branch, Polish Humic Substances Society: Wrocław, Poland, ISBN 978-83-934096-4-8.KabałaC.BekierJ.BińczyckiT.BogaczA.BojkoO.CuskeM.Ćwieląg-PiaseckaI.DębickaM.GałkaB.GersztynL.2015Soils of Lower Silesia: Origins, Diversity and ProtectionKabałaC.Ed.;Wrocław Branch, Polish Humic Substances SocietyWrocław, PolandISBN 978-83-934096-4-8.Search in Google Scholar
Wang X., Xu Y. (2021), Impact of the Depth of Diaphragm Wall on the Groundwater Drawdown during Foundation Dewatering Considering Anisotropic Permeability of Aquifer. Water, 13, 418.WangX.XuY.2021Impact of the Depth of Diaphragm Wall on the Groundwater Drawdown during Foundation Dewatering Considering Anisotropic Permeability of Aquifer13418Search in Google Scholar
Rybak J., Ivannikov, A., Kulikova, E., Żyrek, T. (2018), Deep excavation in urban areas – Defects of surrounding buildings at various stages of construction. MATEC Web Conf., 146, 2012,RybakJ.IvannikovA.KulikovaE.ŻyrekT.2018Deep excavation in urban areas – Defects of surrounding buildings at various stages of construction1462012Search in Google Scholar
Woods R. D. (1997), Dynamic effects of pile installations on adjacent structures, NCHRP 253. Washington, D.C.: National Academy Press, 86 pp., Transportation Research Board.WoodsR. D.1997Washington, D.C.National Academy Press86 pp., Transportation Research Board.Search in Google Scholar
Clough G. W., Chameau J. L. (1980), Measured effects of vibratory sheetpile driving. Journal of Geotechnical Engineering Division, ASCE 106(10): 1081–99.CloughG. W.ChameauJ. L.1980Measured effects of vibratory sheetpile driving10610108199Search in Google Scholar
Linehan P.W., Longinow A., Dowding C.H. (1992), Pipe response to pile driving and adjacent excavation. Journal of Geotechnical Engineering, ASCE 118(2):300–16.LinehanP.W.LonginowA.DowdingC.H.1992Pipe response to pile driving and adjacent excavation118230016Search in Google Scholar
Drabkin S., Lacy H., Kim D. S. (1996) Estimating settlement of sand caused by construction vibration. Journal of Geotechnical Engineering, ASCE 122(11):920–8.DrabkinS.LacyH.KimD. S.1996Estimating settlement of sand caused by construction vibration122119208Search in Google Scholar